Improved Random Incomplete Coloring for Interference Mitigation in Wireless Body Area Networks

Sun Yan-zan; Jiang Yu-feng; Wu Ya-ting; Ma Yi-ming; Fang Yong

doi:10.11999/JFIT141621

Volume 37 Issue 9

Sep. 2015

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Article Navigation > Journal of Electronics & Information Technology > 2015 > 37(9): 2204-2210

Sun Yan-zan, Jiang Yu-feng, Wu Ya-ting, Ma Yi-ming, Fang Yong. Improved Random Incomplete Coloring for Interference Mitigation in Wireless Body Area Networks[J]. Journal of Electronics & Information Technology, 2015, 37(9): 2204-2210. doi: 10.11999/JFIT141621

Citation:

Sun Yan-zan, Jiang Yu-feng, Wu Ya-ting, Ma Yi-ming, Fang Yong. Improved Random Incomplete Coloring for Interference Mitigation in Wireless Body Area Networks[J]. Journal of Electronics & Information Technology, 2015, 37(9): 2204-2210. doi: 10.11999/JFIT141621

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Improved Random Incomplete Coloring for Interference Mitigation in Wireless Body Area Networks

doi: 10.11999/JFIT141621

Received Date: 2014-12-18
Rev Recd Date: 2015-03-25
Publish Date: 2015-09-19

Abstract

Abstract

An Improved Random Incomplete Coloring (IRIC) algorithm is proposed based on Random Incomplete Coloring (RIC) to mitigate inter-Wireless Body Area Network (WBAN) interference. The proposed IRIC algorithm can realize high resource spatial reuse by controlling colored nodes to participate in next round of coloring, and the fairness is also guaranteed by restricting the gap of assigned color amounts between adjacent nodes. Simulation results show that the proposed IRIC algorithm can further improve the system throughput and resource spatial reuse.
- Wireless Body Area Network (WBAN),
- Resource scheduling,
- Random Incomplete Coloring (RIC),
- Spatial reuse

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References(16)

References

Movassaghi S, Abolhasan M, Lipman J, et al.. Wireless body area networks: A survey[J]. IEEE Journal on Communications Surveys Tutorials, 2014, 16(3): 1658-1686.

Yang Wen-bin and Sayrafian-Pour K. Interference mitigation for body area networks[C]. IEEE Conference on 22nd International Symposium on Personal Indoor and Mobile Radio Communications (PIMRC), Toronto, 2011: 2193-2197.

De Silva B, Natarajan A, and Motani M. Inter-user interference in body sensor networks: preliminary investigation and an infrastructure based solution[C]. IEEE Conference on Sixth International Workshop on Wearable and Implantable Body Sensor Networks, Berkeley, 2009: 35-40.

Dong J and Smith D. Cooperative body-area- communications: enhancing coexistence without coordination between networks[C]. IEEE Conference on 23rd International Symposium on Personal Indoor and Mobile Radio Communication (PIMRC), Sydney, 2012: 2269-2274.

Fang Geng-fa, Dutkiewicz E, Yu Ke-gen, et al.. Distributed internetwork interference coordination for wireless body area networks[C]. IEEE Conference on Global Telecommunications Conference (GLOBECOM 2010), Miami, 2010: 1-5.

Kazemi R, Vesilo R, Dutkiewicz E, et al.. Inter-network interference mitigation in wireless body area networks using power control games[C]. IEEE Conference on International Symposium on Communications and Information Technologies (ISCIT), Tokyo, 2010: 81-86.

Kazemi R, Vesilo R, Dutkiewicz E, et al.. Reinforcement learning in power control games for internet work interference mitigation in wireless body area networks[C]. IEEE Conference on International Symposium on Communications and Information Technologies (ISCIT), Australia, 2012: 256-262.

Zhang Zhao-yang, Wang Hong-gang, Wang Chong-gang, et al.. Interference mitigation for cyber-physical wireless body area network system using social networks[J]. IEEE Transactions on Emerging Topics in Computing, 2013, 1(1): 121-132.

Dong Jie and Smith D. Joint relay selection and transmit power control for wireless body area networks coexistence[C]. IEEE International Conference on Communications (ICC), Australia, 2014: 5676-5681.

Dong Jie and Smith D. Opportunistic relaying in wireless body area networks: Coexistence performance[C]. IEEE International Conference on Communications (ICC), Hungary, 2013: 5613-5618.

Movassaghi S, Abolhasan M, and Smith D. Smart spectrum allocation for interference mitigation in Wireless Body Area Networks[C]. IEEE International Conference on Communications (ICC), Australia, 2014: 5688-5693.

Jamthe A, Mishra A, and Agrawal D P. Scheduling schemes for interference suppression in healthcare sensor networks[C]. IEEE International Conference on Communications (ICC), Australia, 2014: 391-396.

Cheng Shih-heng and Huang Ching-yao. Coloring-based inter-WBAN scheduling for mobile wireless body area networks[J]. IEEE Transactions on Parallel and Distributed Systems, 2013, 24(2): 250-259.

Gandham S, Dawande M, and Prakash R. Link Scheduling in wireless sensor networks: distributed edge-coloring revisited[C]. IEEE Conference on 24th Annual Joint Conference of the IEEE Computer and Communications Societies, Miami, USA, 2005, 4: 2492-2501.

Fonseca Jr B J B. An augmented graph-based coloring scheme to derive upper bounds for the performance of distributed schedulers in CSMA-based mobile Ad Hoc networks[C]. IEEE Conference on Wireless Communication and Mobile Computing, Wuhan, 2006: 761-766.

Sun Yan-zan, Hu Hong-lin, Liu Fu-qiang, et al.. Dynamic spectrum access based on MAC-layer spectrum sensing and prior channel pre-allocation strategy[J]. IEICE Transactions on Communications, 2010, E93-B(3): 609-619.

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